Pulse width modulator with two-way integrator

ABSTRACT

An example PWM includes a driver and a two-way oscillator. The oscillator includes, a first frequency adjust current source, a second frequency adjust current source, a capacitor, a switching reference and a comparator. The capacitor integrates a frequency adjust current by charging with the first frequency adjust current source. The capacitor subsequently integrates a second frequency adjust current by discharging with the second frequency adjust current source. The switching reference outputs a first reference voltage and a second reference voltage responsive to an oscillator signal. The comparator compares the output of the switching reference with a voltage on the capacitor. The first and second frequency adjust current sources vary the first and second frequency adjust currents to vary the frequency of the PWM signal to spread energy of switching harmonics over a frequency band and to reduce EMI.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No. 13/111,860, filed on May 19, 2011, now pending, which is a continuation of U.S. patent application Ser. No. 12/477,052, filed on Jun. 2, 2009, now issued as U.S. Pat. No. 7,965,151. U.S. patent application Ser. No. 13/111,860 and U.S. Pat. No. 7,965,151 are hereby incorporated by reference.

BACKGROUND INFORMATION

1. Field of the Disclosure

The present invention relates generally to a pulse width modulator, and more specifically, a pulse width modulator with a two-way integrator.

2. Background

A pulse width modulator (PWM) is a circuit that may be used in applications such as, but not limited to, motor control, switching power converters, or data transmission. A pulse width modulator may output a PWM signal that is a logic signal that switches between two logic states, such as a logic high state and a logic low state. In one design of a PWM, a capacitor may be used to integrate an input current representative of an input signal to determine a duty ratio during each sequential period of the PWM signal. The PWM signal is designed to vary the duty ratio according to one or more inputs. More specifically, the duty ratio may be defined as the ratio of time the PWM signal is in a certain logic state over a given time period. Typically, duty ratio is the amount of time the PWM signal is in the logic high state over a given period T_(S). A period T_(S), may be defined as the time duration of one complete cycle of the PWM signal. More specifically, a complete cycle of the PWM signal may be defined by the duration of time between when the PWM signal is switched to the first state and when the PWM signal is again switched to the first state.

A practical consideration in designing a PWM is determining the maximum duty ratio of the PWM signal. This can be important for many possible reasons. In the PWM that includes a capacitor to integrate, it may be necessary to control the maximum duty ratio such that enough time is available to allow the capacitor to reset (discharge), so it can be ready to integrate at the start of the next period T_(S). For example, if a maximum duty ratio is set to 99% while maintaining the PWM signal frequency above 66 KHz, the capacitor will only have 1% of the period, which is 150 ns, to reset the capacitor before start of the next period T_(S).

To further complicate the issue, the design of the capacitor used may also have a non-linearly changing capacitance at low voltages. In order to maintain proper functionality of the pulse width modulator, an offset to the voltage range in which the capacitor is allowed to integrate is implemented such that integration of the input current occurs where the capacitor value operates in a linear range. For example, due to the nature of the materials used for capacitors in an integrated circuit, the capacitor may integrate inconsistently when a voltage across the capacitor is under 1V, and thus the capacitor may only integrate starting from an offset voltage of 1V. This prevents the capacitor from using a ground node (0 V) and being reset to zero V. Therefore, the capacitor must not only be able to reset within a short time frame because of a high duty cycle (i.e 99%), but also may need to reset to a pre-determined set voltage reference (i.e 1V) to avoid integrating in a non-linear region of the capacitor.

In one example, an LED (light emitting diode) light source is powered by a source of dc power. Because power is generally delivered through a wall outlet as high-voltage ac power, a device, such as a power converter, is required to transform the high-voltage ac power to usable dc power for the LED light source. In operation, a power converter controller, included in the power converter, may output a PWM signal to drive a power switch of the power converter to control the amount of power delivered to the LED light source. In one example, feedback information representative of the output voltage and/or output current at the LED light source may be input to the PWM to adjust the duty ratio of the PWM signal. In this manner, a desired output voltage, output current, and/or output power at the output of the power converter may be regulated.

BRIEF DESCRIPTION OF THE DRAWINGS

Non-limiting and non-exhaustive embodiments and examples of the present invention are described with reference to the following figures, wherein like reference numerals refer to like parts throughout the various views unless otherwise specified.

FIG. 1 is a functional block diagram illustrating an example pulse width modulator (PWM) including a two-way integrator and a timer, in accordance with the teachings of the present invention.

FIG. 2 further illustrates the two-way integrator included in the example PWM of FIG. 1, in accordance with the teachings of the present invention.

FIG. 3 is a timing diagram illustrating particular waveforms of signals associated with the PWM of FIG. 1, in accordance with the teachings of the present invention.

FIG. 4 is a functional block diagram illustrating a pulse width modulator (PWM) including a two-way integrator and a two-way oscillator, in accordance with the teachings of the present invention.

FIG. 5 is a timing diagram illustrating particular waveforms of signals associated with the PWM of FIG. 4, in accordance with the teachings of the present invention.

FIG. 6 further illustrates the two-way integrator included in the example PWM of FIG. 4, in accordance with the present invention.

FIG. 7 is a functional block diagram illustrating a pulse width modulator (PWM) including a two-way integrator and a two-way oscillator including additional offset current sources, in accordance with the teachings of the present invention.

DETAILED DESCRIPTION

A two-way integrator included in a PWM to allow for increasing a maximum duty ratio of a PWM signal is disclosed. More specifically, a duty ratio in a period of a PWM signal is to be set by charging a capacitor from a first reference to a second reference and a duty ratio in a subsequent period of the PWM signal is to be set by discharging the capacitor from the second reference to the first reference. It will be apparent, however, to one having ordinary skill in the art that the specific detail need not be employed to practice the present invention. In other instances, well-known materials or methods have not been described in detail in order to avoid obscuring the present invention.

Reference throughout this specification to “one embodiment”, “an embodiment”, “one example” or “an example” means that a particular feature, structure or characteristic described in connection with the embodiment or example is included in at least one embodiment of the present invention. Thus, appearances of the phrases “in one embodiment”, “in an embodiment”, “one example” or “an example” in various places throughout this specification are not necessarily all referring to the same embodiment or example. Furthermore, the particular features, structures or characteristics may be combined in any suitable combinations and/or subcombinations in one or more embodiments or examples. In addition, it is appreciated that the figures provided herewith are for explanation purposes to persons ordinarily skilled in the art and that the drawings are not necessarily drawn to scale.

Referring now to FIG. 1, a functional block diagram illustrates a pulse width modulator (PWM) 100, in accordance with the teachings of the present invention. In the example embodiment of FIG. 1, PWM 100 includes a two-way integrator 102, a timer 104, and a driver 106. As shown, two-way integrator 102 is coupled to output a duty ratio signal U_(DR) to driver 106 and timer 104 is coupled to output a pulse signal U_(PULSE) to driver 106. As further shown, driver 106 outputs a high maximum duty ratio PWM signal U_(PWM), from hereon referred to as PWM signal U_(PWM). In one example, PWM signal U_(PWM) may be used to drive a power switch of a power converter, or may serve as a data transmission signal, or control the drive of a motor. In operation, two-way integrator 102 outputs duty ratio signal U_(DR) in response to an input signal U_(INPUT) and pulse signal U_(PULSE). In one example, input signal U_(INPUT) is representative of any input that will adjust the duty ratio of PWM signal U_(PWM) in response to changes in magnitude of the input signal U_(INPUT). In one example, input signal U_(INPUT) may be representative of, but not limited to, an input voltage, input current, and/or an output voltage of a power converter. In another example, input signal U_(INPUT) may be representative of feedback information to control an output of a motor.

As shown, two-way integrator 102 includes a charge up circuit 108, a charge down circuit 110, a capacitor 112, a switching reference 114, and a comparator 116. In operation, timer 104 outputs pulse signal U_(PULSE) to driver 106 to set sequential periods T_(S) for PWM signal U_(PWM). More specifically, each time pulse signal U_(PULSE) is pulsed, driver 106 sets PWM signal U_(PWM) to a logic high state. In one embodiment, pulse signal U_(PULSE) is such that it sets a constant period T_(S) for PWM signal U_(PWM). In another embodiment, timer 104 may vary pulse signal U_(PULSE) in response to an additional input to vary the length of sequential periods T_(S) of PWM signal U_(PWM). In one embodiment, timer 104 may limit the length of sequential periods T_(S) of pulse signal U_(PULSE) to prevent PWM signal U_(PWM) from dropping below a minimum PWM frequency that may be specified by the application using PWM 100.

In one example embodiment, duty ratio signal U_(DR) sets the duty ratio of PWM signal U_(PWM). More specifically, the duty ratio is the ratio of time the PWM signal U_(PWM) is set in a logic high state with respect to its respective period T_(S). In operation, charge up circuit 108 outputs an input current I_(INPUT). In one example, input current I_(INPUT) is representative of input signal U_(INPUT). In operation, input current I_(INPUT) is received by capacitor 112. More specifically, capacitor 112 begins to integrate input current I_(INPUT) at the start of a period T_(S1), coincident with the pulse signal U_(PULSE) adjusting the PWM signal U_(PWM) to a logic high state. When voltage V_(INT) across capacitor 112 reaches a voltage reference V_(REFH), comparator 116 outputs a duty ratio signal U_(DR) that causes PWM signal U_(PWM) to transition from a logic high state to a logic low state. For a subsequent period T_(S2), capacitor 112 will perform integration of input current I_(INPUT) by discharging capacitor 112 from high voltage reference V_(REFH) to a low voltage reference V_(REFL). As with the prior period, at the start of the period T_(S2), Timer 104 pulses U_(PULSE) which causes driver 106 to set PWM signal U_(PWM) to a logic high state. When the voltage across capacitor 112 reaches low voltage reference V_(REFL), comparator 116 outputs a duty ratio signal U_(DR) that causes PWM signal U_(PWM) to transition from a logic high state to a logic low state. During a next period T_(S3), integration is now performed by, again, charging capacitor 112 from the voltage reference V_(REFL) to the voltage reference V_(REFH). In this manner, the input current representative of an input signal U_(INPUT) is integrated to control a duty ratio of a PWM signal U_(PWM). By employing the two-way integration technique as described in accordance with the teachings of the present invention the maximum duty ratio for a switching period T_(S) may reach 100% since no time may be necessary to reset capacitor 112 to a starting voltage before the next switching period T_(S).

In one example, capacitor 112 is a discrete passive component having a capacitance. In another example, capacitor 112 includes several discrete passive components coupled together having a total effective capacitance. In yet another example, capacitor 112 includes one or more active components that provide an effective capacitance for integrating input current I_(INPUT). In still another example, capacitor 112 may include an integrated circuit, in accordance with the teachings of the present invention.

As shown, switching reference 114 includes a switch 118 that switches between voltage reference V_(REFH) and voltage reference V_(REFL). In operation, when capacitor 112 is charging, switch 118 is in position A and switching reference 114 is representative of voltage reference V_(REFH). When capacitor 112 is discharging, switch 118 is in position B and switching reference 114 is representative of voltage reference V_(REFL). In one example, switching reference 114 outputs a reference signal U_(REF) that is a logic signal indicating whether switch 118 is in position A or position B (i.e., whether switching reference 114 is outputting voltage reference V_(REFH) or voltage reference V_(REFL)).

Referring now to FIG. 2, the two-way integrator 102 in FIG. 1 is further illustrated, in accordance with the teachings of the present invention. As shown, charge up circuit 108 includes a current source 202 that sources a current I_(INPUT), a first switch SW1, a logic AND gate 204, and an inverter 206. As further shown, charge down circuit 110 includes a current source 208 that sinks a current I_(INPUT), a second switch SW2, a logic AND gate 210, and an inverter 212. In operation, charge up circuit 108 conducts input current I_(INPUT) through switch SW1 when output of logic AND gate 204 is in a logic high state. In one example, logic AND gate 204 receives reference signal U_(REF) and duty ratio signal U_(DR) as inputs. According to the illustrated example, reference signal U_(REF) is in a logic high state when switching reference 114 is representative of voltage reference V_(REFH) and is in a logic low state when switching reference 114 is representative of a voltage reference V_(REFL). As a result, switch SW1 conducts input current I_(INPUT) to charge capacitor 112 until the voltage V_(INT) across capacitor 112 reaches reference voltage V_(REFH). When voltage V_(INT) is substantially equal to reference voltage V_(REFH), duty ratio signal U_(DR) is set to a logic high state by comparator 116. As a result, PWM signal U_(PWM) is set to a logic low state. In this manner, the duty ratio of period T_(S1) of PWM signal U_(PWM) is controlled in response to integrating an input current I_(INPUT).

Continuing with the example, pulse signal U_(PULSE) initiates the beginning of a subsequent period T_(S2) by setting PWM signal U_(PWM) from a logic low state to a logic high state. In operation, switching reference 114 may set switch 118 from position A to a position B such that switching reference 114 is representative of a voltage reference V_(REFL) in response to pulse signal U_(PULSE). In one example, switching reference 114 may toggle between positions A and B each time pulse signal U_(PULSE) is set to a logic high state. In this manner, the switching reference 114 will be adjusted from voltage reference V_(REFH) to voltage reference V_(REFL) for period T_(S2) of PWM signal U_(PWM), as shown in the waveforms of FIG. 3. In operation, switch SW2 of charge down circuit 110, conducts input current I_(INPUT) when logic AND gate 210 is set to a logic high state. As a result, switch SW2 conducts input current I_(INPUT) until the voltage V_(INT) across capacitor 112 is discharged to reference voltage V_(REFL). When voltage V_(INT) is substantially equal to reference voltage V_(REFL), duty ratio signal U_(DR) is set to a logic low state by comparator 116. As a result, PWM signal U_(PWM) is set to a logic low state. In this manner, the duty ratio of a subsequent period T_(S2) of PWM signal U_(PWM) is controlled in response to integrating an input current I_(INPUT) by discharging capacitor 112.

In summary, capacitor 112, charge up circuit 108, charge down circuit 110, and comparator 116 function as a two-way integrator that determines a duty ratio of a period T_(S1) of a PWM signal U_(PWM) by charging up capacitor 112 to a voltage reference V_(REFH) and determines a duty ratio for a subsequent period T_(S2) of a PWM signal U_(PWM) by discharging capacitor 112 to a voltage reference V_(REFL).

Referring now to FIG. 3, a timing diagram illustrates signals of PWM 100 in accordance with the teachings of the present invention. As shown, period T_(S1) is defined to be between time t₀ and t₂, and subsequent period T_(S2) is defined to be between time t₂ and time t₄. As shown, waveform 302 illustrates PWM signal U_(PWM). As shown, waveform 304 of pulse signal U_(PULSE) illustrates a pulsed signal at the beginning of every period T_(S). In operation, when pulse signal U_(PULSE) is set to a high logic state (or pulsed), PWM signal U_(PWM) is set to a logic high state that mark the beginning of periods T_(S1) and T_(S2). In this manner, PWM signal U_(PWM) marks the beginning of a new period T_(S) when set to a logic high state. As shown, a waveform 306 illustrating voltage V_(INT) across capacitor 112, reaches voltage reference V_(REFH) at a time t₁. As discussed above, comparator 116 sets duty ratio signal U_(DR) to a logic high state in response to voltage V_(INT) reaching voltage reference V_(REFH). As further shown, PWM signal U_(PWM) switches from a high state to a logic low state in response to duty ratio signal U_(DR) switching logic states. In this manner, duty ratio signal U_(DR) adjusts the duty ratio of PWM signal U_(PWM) during period T_(S1). As shown in waveform 308, reference signal U_(REF) is in a position A, which is representative of logic high state, till a time t₂. In operation, reference signal U_(REF) is set to a position A for the period T_(S1) and is set to a position B for the period T_(S2). As shown, during the subsequent time period T_(S2) which starts at time t₂, capacitor 112 has not been reset during period T_(S1) in order to again perform integration for the subsequent period T_(S2). Instead, two-way integrator 102 performs integration by alternating between charging and discharging capacitor 112 between voltage reference V_(REFH) and V_(REFL). As shown in waveform 306, during time t₁ and t₂ voltage V_(INT) across capacitor 112 is not discharged to reset capacitor 112 to allow for integration by charging during the next time period T_(S2). Instead, capacitor 112 performs integration by discharging capacitor 112 during time period T_(S2) between time t₂ and t₃. This allows substantially zero reset time for capacitor 112 in order to perform integration for capacitor 112, and duty ratio of PWM signal U_(PWM) may be substantially 100%. In one example, voltage reference V_(REFL) is offset from 0 V so that capacitor 112 may only integrate input current I_(INPUT) in a region where the capacitance value of capacitor 112 is relatively constant. In other words, in one example, the capacitor 112 may only charge and discharge between a voltage range which capacitor 112 may operate linearly. In one example, V_(REFL) may be substantially equal to 1V. In another example V_(REFL) may be set to zero.

Referring now to FIG. 4, a functional block diagram illustrates an example pulse width modulator 400, in accordance with the teachings of the present invention. As shown, pulse width modulator 400 includes a two-way integrator 402, a two-way oscillator 404, a driver 406, and PWM logic circuitry 408. In one example, two-way integrator 402, and driver 406 represent possible implementations of two-way integrator 102 and driver 106, respectively of PWM 100. In one example, two-way oscillator 404 performs the same function of setting the period T_(S) of PWM signal U_(PWM) as timer 104 of PWM 100. As shown, two-way integrator 402 is coupled to output duty ratio signal U_(DR) to driver 106, and two-way oscillator 404 is coupled to output an oscillator signal U_(OSC) to driver 406. In one example, oscillator signal U_(OSC) is similar in function to the pulse signal U_(PULSE) used in conjunction with PWM 100. In operation, oscillator signal may be designed to set a period T_(S) of PWM signal U_(PWM). As further shown, driver 406 outputs a high maximum duty ratio PWM signal, U_(PWM), from here on referred to as PWM signal U_(PWM). In operation, two-way integrator 402 outputs duty ratio signal U_(DR) in response to input signal U_(INPUT). As shown, two-way oscillator includes a current source 410, a current source 412, switch SW3, switch SW4, switch SW6, capacitor 414, switching reference 416, comparator 418, and inverter 420. In one example, two-way oscillator 404 functions in a similar manner to two-way integrator 402. In operation, two-way oscillator 404 sets a period T_(S1) for PWM signal U_(PWM) by charging capacitor 414 with current source 410. Similarly, oscillator signal U_(OSC) sets a subsequent period T_(S2) by discharging capacitor 414 with current source 412. In this manner, two-way oscillator 404 outputs oscillator signal U_(OSC) that sets sequential time periods for PWM signal U_(PWM). In operation, switch signal U_(SW3) is set to a logic high state to allow switch SW3 to conduct oscillator current I_(OSC) during period T_(S1) to charge capacitor 414. Conversely, switch signal U_(SW4) is set to a logic high state to allow switch SW4 to conduct oscillator current I_(OSC) during subsequent period T_(S2) to discharge capacitor 414. As shown, comparator 418 receives an oscillator voltage V_(OSC) from capacitor 414 and a voltage reference from switching voltage reference 416. In operation, when comparator 418 switches between logic states, switch signal U_(SW6) switches logic states which switch the voltage reference of switching reference 416. In this manner, switching reference 416 switches between voltage reference V_(REFH) and voltage reference V_(REFL) at the beginning of each period T_(S) of PWM signal U_(PWM). In addition, when comparator 418 switches logic states, oscillator signal U_(OSC) indicates to driver 406 to set PWM signal U_(PWM) to a logic high state.

Referring now to FIG. 5, a timing diagram illustrates signals of PWM 400 in accordance with the teachings of the present invention. As shown, a period T_(S1) is defined to be between time t₀ and t₂, and a subsequent period T_(S2) is defined to be between time t₂ and time t₄. As shown, waveform 502 illustrates PWM signal U_(PWM), for the sake of a timing reference with respect to other signals of PWM 400. As further shown in waveform 504, oscillator signal U_(OSC) switches logic states at times t₂ and t₄, which mark the end of period T_(S1) and subsequent period T_(S2). As shown in waveform 506, oscillator voltage V_(OSC) increases from a reference voltage V_(REFL) to a reference voltage V_(REFH) during period T_(S1). When oscillator voltage V_(OSC) reaches reference voltage V_(REFH), oscillator signal U_(OSC) switches from logic low state to a logic high state. As shown, oscillator voltage V_(OSC) decreases from reference voltage V_(REFH) to V_(REFL) during subsequent switching period T_(S2). When oscillator voltage V_(OSC) reaches reference voltage V_(REFL), oscillator signal U_(OSC) switches from a logic high state to a logic low state. When oscillator signal U_(OSC) switches logic states, PWM signal begins a new period T_(S) and switches PWM signal U_(PWM) from a logic low state to a logic high state. In this manner, U_(OSC) sets sequential periods T_(S) of PWM signal U_(PWM). In one example, sequential periods T_(S) are constant, thus allowing PWM signal U_(PWM) to maintain a constant frequency. As shown in waveform 508, duty ratio signal U_(DR) switches logic states when integration voltage V_(INT), shown in waveform 510, reaches voltage reference V_(REFH) when capacitor 424 is charging or when V_(INT) reaches voltage reference V_(REFL) when capacitor 424 is discharging. In another example, oscillator capacitor 414 and an integrator capacitor 424 are matched such that, the time that it takes capacitors 414 and 424 to charge (or discharge) to one of the voltage references is the same. In yet another example, oscillator capacitor 414 and integrator capacitor 424 are matched and additional offset current sources are added to ensure that integrator capacitor 424 is fully charged/discharged to its reference voltage before the beginning of the next switching period, as will be discussed in more detail below with reference to FIG. 6.

Referring now to FIG. 6, a functional block diagram illustrates the example PWM 600 with additional offset current sources in accordance with the teachings of the present invention. In one example, offset current sources 602 and 604 are included in PWM 600 to ensure that integrator capacitor 424 is charged/discharged to its reference voltage before the beginning of the next switching period. For example, two-way integrator 606 includes additional offset current sources 602 and 604 that produce a current I_(OFF). Thus, in the illustrated example, input current I_(INPUT) is equal to the offset current I_(OFF) plus integrator current I_(INT). In one example, offset current sources 602 and 604 may be used when voltage reference V_(REFH) and V_(REFL) is designed to vary. More specifically, offset current I_(OFF) may incorporate the changes of voltage references V_(REFH) and V_(REFL). More specifically, voltage references V_(REFH) and V_(REFL) may effectively vary, and still be implemented as constant reference values. This allows the added benefit of effectively varying the voltage reference and still prevents integrator capacitor 424 from having to reset for a next period T_(S), since integrator capacitor 424 is still charging and discharging to fixed voltage references. For example, voltage references V_(REFH) and V_(REFL) may vary as a hyperbolic function when PWM signal U_(PWM) is used in a switching power converter. In another example, offset current sources 602 and 604 allow integrator capacitor 424 to reach reference voltage V_(REFH) or V_(REFL) before the oscillator capacitor (e.g., see oscillator capacitor 414 shown in FIG. 4) reaches reference voltage V_(REFH) or V_(REFL), respectively. More specifically, current sources 602 and 604 provide a fixed current equal to the oscillator current (e.g., oscillator current I_(OSC) shown in FIG. 4), while integrator current I_(INT) is a variable current responsive to the input signal U_(INPUT). In another example, the oscillator capacitor and the integrator capacitor 424 are matched in a way such that if identical currents are injected into each, the resulting voltage rise across each capacitor will be the same. The matching of oscillator and integrator capacitors may ensure that the accuracy of the duty ratio of PWM signal U_(PWM) is maintained across temperature and parameter variations of PWM 600.

With offset current I_(OFF) equal to the value of oscillator current I_(OSC) and integrator current I_(INT) responsive to the input signal U_(INPUT), integrator capacitor 424 will reach voltage reference V_(REFH) or V_(REFL) before the oscillator capacitor reaches voltage reference V_(REFH) or V_(REFL) during each switching period. Thus, in one example, the duration of time that it takes oscillator current to charge the oscillator capacitor to reference voltage V_(REFH) is greater than the duration of time that it takes the input current I_(INPUT) to charge the integrator capacitor 424 to the reference voltage V_(REFH). Similarly, the duration of time that it takes oscillator current to discharge the oscillator capacitor to the reference voltage V_(REFL) is greater than the duration of time that it takes the input current I_(INPUT) to discharge the integrator capacitor 424. In another example, I_(OFFSET) may be used to adjust the maximum duty ratio of PWM signal U_(PWM) by increasing the current in the integrator capacitor 424 to reach voltage reference V_(REFH) or V_(REFL) at a faster rate. In one embodiment, voltage references V_(REFH) and V_(REFL) may be different values for integrator capacitor 424 and oscillator capacitor 414.

Referring now to FIG. 7, a functional block illustrates the example PWM 400 with additional current sources in accordance with the teachings of the present invention. As shown, additional current sources 702 and 704 are included in two-way integrator 402 that output frequency adjust current I_(FREQ1) and additional current sources 706 and 708 are included in two-way oscillator 404 output frequency adjust current I_(FREQ2). In one example, frequency adjust currents I_(FREQ1) and I_(FREQ2) may be adjusted to change the frequency of PWM signal U_(PWM) and still keep the duty ratio of PWM signal U_(PWM) constant. In one example, frequency adjust current I_(FREQ1) and I_(FREQ2) may vary. In another example, frequency adjust current I_(FREQ1) and I_(FREQ2) may be adjusted in response to an input (not shown). In one example this allows a jittering of the frequency of PWM signal U_(PWM). This feature, allows for varying the switching frequency over a specified range to spread the energy of switching harmonics over larger frequency bands and reduce electromagnetic interference (EMI).

The above description of illustrated examples of the present invention, including what is described in the Abstract, are not intended to be exhaustive or to be limitation to the precise forms disclosed. While specific embodiments of, and examples for, the invention are described herein for illustrative purposes, various equivalent modifications are possible without departing from the broader spirit and scope of the present invention. Indeed, it is appreciated that the specific voltages, currents, frequencies, power range values, times, etc., are provided for explanation purposes and that other values may also be employed in other embodiments and examples in accordance with the teachings of the present invention.

These modifications can be made to examples of the invention in light of the above detailed description. The terms used in the following claims should not be construed to limit the invention to the specific embodiments disclosed in the specification and the claims. Rather, the scope is to be determined entirely by the following claims, which are to be construed in accordance with established doctrines of claim interpretation. The present specification and figures are accordingly to be regarded as illustrative rather than restrictive. 

1. A pulse width modulator (PWM), comprising: a driver coupled to output a first and a subsequent period of a PWM signal, wherein each period includes the PWM signal changing between first and second states; a two-way oscillator to generate an oscillator signal, the two-way oscillator including: a first frequency adjust current source coupled to source a first frequency adjust current; a second frequency adjust current source coupled to sink a second frequency adjust current; a first capacitor coupled to integrate the first frequency adjust current by charging with the first frequency adjust current source during the first period of the PWM signal, wherein the first capacitor is further coupled to integrate the second frequency adjust current by discharging with the second frequency adjust current source during the subsequent period of the PWM signal; a first switching reference coupled to output a first reference voltage during the first period of the PWM signal responsive to the oscillator signal, and to output a second reference voltage during the subsequent period of the PWM signal responsive to oscillator signal; and a first comparator coupled to compare the output of the first switching reference with a voltage on the first capacitor and to generate the oscillator signal in response thereto, wherein the driver determines a frequency of the PWM signal in response to the oscillator signal, and wherein first and second frequency adjust current sources vary the first and second frequency adjust currents, respectively, to vary the frequency of the PWM signal to spread energy of switching harmonics over a frequency band and to reduce electromagnetic interference (EMI).
 2. The PWM of claim 1, wherein the first frequency adjust current is substantially equal to the second frequency adjust current.
 3. The PWM of claim 1, wherein the first reference voltage is greater than the second reference voltage.
 4. The PWM of claim 1, wherein the first reference voltage and second reference voltage are both greater than zero.
 5. The PWM of claim 1, wherein the driver determines the frequency of the PWM signal by adjusting the PWM signal from the second state to the first state when a voltage across the first capacitor reaches the first reference voltage during the first period and when the voltage across the first capacitor reaches the second reference voltage during the subsequent period.
 6. The PWM of claim 1, further comprising a two-way integrator, including: a first current source coupled to source a first input current that is representative of an input signal and that varies as a magnitude of the input signal changes; a second current source coupled to sink a second input current that is representative of the input signal and that varies as the magnitude of the input signal changes; a third frequency adjust current source coupled the first current source to source a third frequency adjust current; a fourth frequency adjust current source coupled to the second current source to sink a fourth frequency adjust current; a second capacitor coupled to integrate a sum of the first input current and the third frequency adjust current by charging with the first current source and with the third frequency adjust current source during the first period of the PWM signal, wherein the capacitor is further coupled to integrate a sum of the second input current and the fourth frequency adjust current by discharging with the second current source and with the fourth frequency adjust current source during the subsequent period of the PWM signal; a second switching reference coupled to receive the oscillator signal, wherein the switching reference is coupled to output a third reference voltage during the first period of the PWM signal responsive to the oscillator signal, and to output a fourth reference voltage during the subsequent period of the PWM signal responsive to oscillator signal; and a second comparator coupled to compare the output of the second switching reference with a voltage on the second capacitor and to generate a duty ratio signal in response thereto, wherein the driver determines a first duty ratio of the first period and a subsequent duty ratio of the subsequent period by adjusting the PWM signal to the second state in response to the duty ratio signal, and wherein the third and fourth frequency adjust current sources vary the third and fourth frequency adjust currents, respectively to maintain a constant duty ratio of the PWM signal with respect to changes in frequency of the PWM signal.
 7. The PWM of claim 6, wherein the first and second capacitors are matched.
 8. The PWM of claim 6, wherein a first time duration of the first capacitor charging to the first reference voltage is greater than a second time duration of the second capacitor charging to the third reference voltage.
 9. The PWM of claim 6, wherein the third frequency adjust current is substantially equal to the fourth frequency adjust current.
 10. The PWM of claim 6, wherein the third reference voltage is greater than the fourth reference voltage.
 11. The PWM of claim 6, wherein the third reference voltage and the fourth reference voltage are both greater than zero.
 12. The PWM of claim 6, wherein the input current is representative of an input signal that is a voltage, current, or a combination of the two.
 13. The PWM of claim 6, wherein integration by charging the first capacitor and integration by charging the second capacitor starts at a beginning of the first period.
 14. The PWM of claim 6, wherein integration by discharging the first capacitor and integration by discharging the second capacitor starts at a beginning of the subsequent period. 